Gradient Estimates Under Integral Curvature Conditions
Abstract
This thesis contains two main results: a Li-Yau type gradient estimate 3.3.1, and
a Zhong-Yang type eigenvalue estimate 4.3.1. The classical version of these results is formulated in the setting of manifolds with nonnegative Ricci curvature. Here we present
proofs of analogous results under integral curvature assumptions, which are more general
and apply in many more settings than pointwise lower bounds. Although the totality of this
work has not been published, part of it was published in [RO19] or appears in the preprint
[ROSWZ18].
The Li-Yau gradient estimate that we prove is an inequality satisfied by the gradient of the Neumann heat kernel. We restrict our attention to compact domains within
an ambient space manifold, and assume that the amount of negative Ricci curvature of the
manifold is small in an Lp average sense. The domains are not necessarily convex, but must
satisfy an interior rolling R-ball condition 1.3.4. As a corollary of this theorem, we derive
a parabolic Harnack inequality 3.4.1 and a mean value inequality 3.4.2, as well as a lower
bound for the first nontrivial Neumann eigenvalue on this class of domains 3.4.3.
The Zhong-Yang type estimate that we present is a lower bound for the first
nonzero eigenvalue of the drift Laplacian in the setting of closed smooth metric measure
spaces. It is derived assuming that the amount of negative Bakry-Émery Ricci curvature
of the manifold is small in an Lp average sense. The estimate is sharp, since it recovers the
classical result in the limit where the Ricci tensor is nonnegative. Moreover, we show that
the smallness of the curvature assumption is necessary in example 4.4.2.